They're densely packed with assumptions that I've read the latest in whatever branch of discrete math, category theory or abstract algebra is popular this week. (If I never read the words "consult the paper whatever for details of implementation" again, it will be too soon.)

Er, and what about simple first-order logic? `forall`

is pretty clearly in reference to universal quantification, and in that context the term existential makes more sense as well, though it would be less awkward if there were an `exists`

keyword. Whether quantification is effectively universal or existential depends on the placement of the quantifier relative to where the variables are used on which side of a function arrow and it's all a bit confusing.

So, if that doesn't help, or if you just don't like symbolic logic, from a more functional programming-ish perspective you can think of type variables as just being (implicit) *type* parameters to the function. Functions taking type parameters in this sense are traditionally written using a capital lambda for whatever reason, which I'll write here as `/\`

.

So, consider the `id`

function:

```
id :: forall a. a -> a
id x = x
```

We can rewrite it as lambdas, moving the "type parameter" out of the type signature and adding inline type annotations:

```
id = /\a -> (\x -> x) :: a -> a
```

Here's the same thing done to `const`

:

```
const = /\a b -> (\x y -> x) :: a -> b -> a
```

So your `bar`

function might be something like this:

```
bar = /\a -> (\f -> ('t', True)) :: (a -> a) -> (Char, Bool)
```

Note that the type of the function given to `bar`

as an argument depends on `bar`

's type parameter. Consider if you had something like this instead:

```
bar2 = /\a -> (\f -> (f 't', True)) :: (a -> a) -> (Char, Bool)
```

Here `bar2`

is applying the function to something of type `Char`

, so giving `bar2`

any type parameter other than `Char`

will cause a type error.

On the other hand, here's what `foo`

might look like:

```
foo = (\f -> (f Char 't', f Bool True))
```

Unlike `bar`

, `foo`

doesn't actually take any type parameters at all! It takes a function that *itself* takes a type parameter, then applies that function to two *different* types.

So when you see a `forall`

in a type signature, just think of it as a **lambda expression for type signatures**. Just like regular lambdas, the scope of `forall`

extends as far to the right as possible, up to enclosing parenthesis, and just like variables bound in a regular lambda, the type variables bound by a `forall`

are only in scope within the quantified expression.

*Post scriptum*: Perhaps you might wonder--now that we're thinking about functions taking type parameters, why can't we do something more interesting with those parameters than put them into a type signature? The answer is that we can!

A function that puts type variables together with a label and returns a new type is a *type constructor*, which you could write something like this:

```
Either = /\a b -> ...
```

But we'd need completely new notation, because the way such a type is written, like `Either a b`

, is already suggestive of "apply the function `Either`

to these parameters".

On the other hand, a function that sort of "pattern matches" on its type parameters, returning different values for different types, is a *method of a type class*. A slight expansion to my `/\`

syntax above suggests something like this:

```
fmap = /\ f a b -> case f of
Maybe -> (\g x -> case x of
Just y -> Just b g y
Nothing -> Nothing b) :: (a -> b) -> Maybe a -> Maybe b
[] -> (\g x -> case x of
(y:ys) -> g y : fmap [] a b g ys
[] -> [] b) :: (a -> b) -> [a] -> [b]
```

Personally, I think I prefer Haskell's actual syntax...

A function that "pattern matches" its type parameters and returns an arbitrary, existing type is a *type family* or *functional dependency*--in the former case, it even already looks a great deal like a function definition.